DE3019877C2 - Device and method for changing oil in an internal combustion engine - Google Patents

Description

corresponding high pressure fuel channels 22.

The internal combustion engine also includes a lubrication system with an oil pan 24 from which oil is supplied different parts of the machine by means of an oil pump (not shown) and then into the Oil pan 24 returned. The lubrication system of the device according to the invention communicates via a bypass port 26 with the engine lubrication downstream of the oil pump.

Oil delivery means comprise an oil line 28, one end of which is connected to the lubrication system via a bypass opening 26 is connected and which leads to the fuel tank 14. An electromagnetic valve 30 is in the Oil line 28 arranged to the flow of the used machine oil from the lubrication system to regulate fuel system for mixing with fuel.

oil feed means include an oil feed line 34, which one oil tank 3? with <Ιργ oil pan 24 connects. An electromagnetic valve 36 is switched on in the oil feed line 34 in order to feed fresh oil into to regulate the oil pan. The oil is from the oil tank 32 to the Oil pan 24 promoted by gravity because the oil tank 32 is arranged at a higher level than the oil pan 24.

in the following, with reference to FIG. 2 in conjunction with FIG. 1 the control of the electromagnetic Valves 30 and 36 described. The solenoid valve 30 is normally closed. Then no oil can flow through the oil line 28. When the solenoid valve 30 is actuated, oil can flow through the oil line 28, so that the oil conveyor is in working order. As in Fig. As shown in FIG. 2, a timer 38 is provided which is used for remains switched on for a certain period of time when an odometer switch 40 is closed. The timer 38 is electrical via a safety switch 42 and an ignition switch 44 with a battery 46 connected. The safety switch 42 is normally closed and then if necessary opened when the oil tank 32 is nearly empty or if for some reason it is preferred, used oil Do not pull it out of the machine to prevent oil from leaking out of the lubrication system.

The odometer switch 40 is always closed when the motor vehicle has a predetermined Has traveled. According to Figure 2, the solenoid valve 30 is electrically connected to the timer 38, the Safety switch 42, the ignition switch 44 and the battery 46 are connected so that it is supplied with power from the Battery 46 is supplied.

The solenoid valve 36 is normally closed. In this case, no oil can pass through the oil feed line 34 stream. When the solenoid valve 30 is actuated, fresh oil can flow through the oil feed line 34, so that the Oil feed media are in operating condition. As in Fig.2 shown, a timer 48 is provided for a remains on for a predetermined period of time when both an oil level switch 50 and an oil pressure switch are closed. The timer 48 is electrically over an ignition switch 44 is connected to the battery 46. The oil level switch 50 is normally open but closed when the oil level in the oil pan drops below a predetermined level Oil pressure switch 52 is normally open, but is closed when the oil pressure in the lubrication system drops below a predetermined pressure As can be seen from Figure 2, the solenoid valve 36 is electrical connected to the timer 48, the ignition switch 44 and the battery 46 so that it is supplied with power will.

Based on the F i g. 3A and 3B, the structure of the odometer switch 40 will now be described. As shown the odometer switch 40 assigned to an odometer 54 or odometer, the several number wheels having. A movable contact piece 56 of the odometer switch 40 is attached to a number wheel 60, which indicates the order of magnitude of 10 km, with the contact piece in a peripheral surface of the number wheel 60 is embedded. The odometer switch 40 comprises a stationary contact part 58 which is arranged in a stationary manner, so that the movable contact piece 56 is in contact with the stationary contact part 58 with each revolution of the

is number wheel 60 reached. It is now understandable that the Odometer switch 40 closes every time the motor vehicle has driven 100 km.

In the following, the operation of the embodiment shown in F i g l his 3B will be described. It is assumed that the ignition switch 44 and the safety switch 42 are closed. When the odometer switch 40 closes after driving a distance of 100 km, the timer 38 is switched on for the predetermined period of time. During this period of time, the solenoid valve 30 is open and thus allows oil to flow through the oil line 28 to the fuel tank 14. The amount of machine oil which flows through the oil line 28 is proportional to the predetermined period of time during which the timer 38 is switched on. The used machine oil is mixed with the fuel in the fuel tank 14. This mixture of machine oil and fuel is conveyed via the fuel feed line 16 by means of the fuel injection pump 12 to the injection nozzles 20 and is injected into the combustion chambers where the mixture of machine oil and fuel is burned.

If the oil level in the oil pan 24 falls below a predetermined level as a result of oil drainage from the lubrication system or from any other Basically, the oil level switch 50 of the oil pan 24 closes. The oil pressure switch 52 remains open, as long as the internal combustion engine is operating because the oil pressure is high so that the timer 48 is turned off remains as long as the internal combustion engine is in operation. However, if the oil pressure switch 52 closes when the The machine is at a standstill before it is started or if the oil pressure falls below the predetermined value for any other reason If the minimum pressure drops, the timer 48 switches on for a certain period of time and operates thus the solenoid valve 36, so that in the Ölv.nk 32 stored fresh oil can flow through the oil feed line 34 to the oil pan 24. In this way, the oil level in the oil pan 24 is kept at an appropriate level. The through the oil feed line 34 The amount of oil flowing is proportional to the predetermined length of time for which the timer 48 is switched on is

The oil pressure switch 52 is provided for the purpose of that overfilling of the oil pan 24 is avoided, which could otherwise occur when the oil level switch due to a temporary drop in the oil level below the predetermined level due to machine vibrations or delays in restoring the initial level immediately after the Starting the machine because of the high viscosity of the oil closes. Therefore, fresh oil is only added to the Oil sump fed in when the oil level is low and

when the oil pressure is below a predetermined minimum value.

The length of time during which the timer 48 is switched on determines the amount of fresh oil, which is fed into the oil pan. This period of time should be measured so that even with a faulty actuation signal, the oil level does not exceed> increases moderately.

It is now clear that because of the removal of a small amount of oil from the machine oil that has been used Lubrication system and replacement with a small amount of fresh oil, the usual oil change has become superfluous and that the machine oil in the lubrication system is continuously replaced in order to maintain a constant degree of purity of the oil. Because that stake of the machine oil drained from the lubrication system is burned together with the fuel is, the usual problem of changing and Ahfijhrpns used oil is eliminated.

With regard to the decision as to which amount of used oil should be discharged from the lubrication system, in the case of a diesel engine with an oil supply of 51 and an oil change interval of 5000 km, an oil quantity of 100 cm ³ per 100 km of driving distance can be discharged. Assuming that the fuel consumption is 101 per 100 km, it can be concluded that 100 cm ^{3 of} machine oil is mixed with 10 l of fuel. It follows that the fuel / waste oil ratio is 100: 1. This ratio is far lower than the fuel / oil ratio of a mixture used in two-stroke internal combustion engines. Consequently, no problem arises. Although the addition of oil causes insufficient fuel atomization, the combustion is not deteriorated in any case in diesel engines.

Of course, it is theoretically possible to remove, for example, 1 cm ^{3 of used} oil from the lubrication system: however, such a fine control is difficult to carry out and not practical.

The function of the safety switch 42 is to prevent oil from leaving the lubrication system is discharged when the oil tank 32 is almost empty or if for another reason it is preferred, Do not drain used oil out of the machine. The safety switch 42 can be operated by hand.

Preferably, the oil tank 32 is made of a transparent or semi-transparent material Manufactured to facilitate inspection.

Although in the execution described above, used oil Is discharged via the bypass opening 26, the used oil can also be discharged from the oil pan 24, if an electrically operated pump replaces the solenoid valve 30. In this case, the electric pump of be of the type that it shuts off when not in use

Although in the embodiment described, the oil tank 32 is at a higher level than the oil pan 24 is arranged to allow a gravity flow, the solenoid valve 36 can also from a electrically operated pump must be replaced. It is also possible to connect the oil feed line 34 to the suction side of the To connect machine oil pump (not shown) and thus save the solenoid valve 36.

It is of course also possible that the period of time during which the timer 38 is switched on, and / or the length of time during which the timer 48 is switched on to vary in order to allow variable control of the waste oil removal and fresh oil supply cause.

With reference to FIGS. A second embodiment will now be described from 4 to 8. Like F i g. 4 shows is the second embodiment of a device according to the invention similar to the first embodiment of FIG. 1, however, differs from it in the following respects. In the second embodiment, instead of a solenoid valve 36, the oil feed means comprise a float valve 62 and a valve 64 of the "open-close" type. As in

ίο F i g. 4, an oil feed line 34 leads to one oil pan 24, and the on-off valve 64 is in the line 24 switched on. The valve 64 is in connection with the ignition switch of the machine and with a Alarm buzzer operated so that the valve 64 the

Oil feed line 34 shuts off when the machine ignition switch is open (turned off) or when the alarm buzzer is actuated.

As best seen in Fig. 5A can be seen, the oil feed line 34 ends in a valve seat 68 of the Float valve 62. The float valve 62 comprises a float 70 which is attached to a valve member 66, which the seat 68 when reaching a the predetermined oil level in the oil pan closes. When the oil level in the oil pan 24 is above the predetermined oil level also rises, the float 70 moves up and lifts the valve member 66 to close the seat 68, while falling oil level below the predetermined oil level Float 70 to move down and thus

caused the seat to open. Preferably that is Float valve 62 is arranged in the central region of the oil pan 24.

If the float reacts too sensitively to fluctuations in the oil level in the oil pan 24, the float is preferably in a housing according to FIG. 5B and 5C arranged. That in it shown modified float valve 62 'differs from the float valve 62 only in that a enclosing housing 74 is provided.

The housing 74 is provided with at least one air leakage hole 74a on its top wall and with at least one hole 74b in an area which is normally immersed in oil in the oil pan 24. The housing 74 acts as a shield to turn off the Effect of sudden, temporary fluctuations in the oil level in the oil pan 24, which arise from vehicle movement, increased oil viscosity or the like, in that the oil flow between the oil pan and the housing is throttled through the hole 74b. Thus can

an undesired opening of the modified float valve 62 'can thus be avoided. The oil level can therefore in the oil pan 24 in this way with greater accuracy at a predetermined level being held.

The device according to FIG. 4 also differs from that based on FIG. 1 described Device in that the oil conveying means mechanical means according to FIGS. 6A and 6B or according to F i g. 7A, 7B and 7C for the purpose of controlling the Have discharged from the lubrication system amount of oil, so that the electromagnetic valve 30 and the associated control circuit are avoided. Another difference is in the way that the oil delivery line is connected An oil line 76, which comes from the lubrication system is with a Fuel return line 16a of a fuel system tied together. The fuel return line 16a leads from a fuel injection pump 12 to a combustion

fuel tank 14 and delivers fuel from the injection pump 12 back to the fuel tank 14. In the In the oil line 76, a valve 78 of the open-close type is switched on, which is shut off to allow oil to be withdrawn to prevent when the machine is not working or when the alarm buzzer is activated. The mechanical Means for metering an amount of oil that is obtained from the Lubrication system is to be withdrawn, are in the following with reference to the F i g. 6A and 6B as well as using the F i g. 7A, 7B and 7C.

According to FIGS. 6A and 6B leads the oil line 76 to a bearing portion of a camshaft 80, the is rotatably supported by a bearing 82. The camshaft 80 is provided with a central oil channel 84 and a channel 86 extending radially therefrom. In the bearing 82 an oil channel 88 is formed, one of which End is connected to the oil line 76. The radial oil channel 86 and the oil channel 88 are in relation to one another aligned that they are with every revolution of the

ϊίΟΓΓιΙΓΓύΠίζΐεΓεπ.

In the mechanical metering device according to FIGS. 6A and 6B will turn once for each revolution when the camshaft 80 comes into an angular position in which the radial oil channel 86 and the oil channel 88 in the Bearing communicates, a quantity of oil is pumped from the central channel 84 into the oil line 76. The amount of oil that flows out of the central channel 84 is determined by the length of time during which the radial oil channel 86 communicates with the oil channel 88, as well as through the cross section of the radial oil channel 86 and by the oil pressure. A small amount of oil flow from the lubrication system can thus easily be set relatively precisely will. The radial oil passage 86 also supplies oil to the cooperating bearing surfaces between the camshaft 80 and the bearing 82.

Another embodiment of a mechanical metering device will now be described with reference to FIGS. 7A, 7B and 7C. The Fig.7A and 7B show the section of a bearing in which oil to a central oil channel 84 of a camshaft 80 via a feed line 90, a circumferential groove 92 and a radial oil channel 86 is funded. An oil channel 88 is used to discharge oil arranged so that it is in communication with a cutout 94 (Fig. 7C) with which the circumferential groove Is provided. such that the cutout 94 with the oil channel 88 once for each revolution of the Camshaft 80 communicates. With this construction is a similar effect as with the construction after the F i g. 6A and 6B scored.

The from the lubrication system by means of the mechanical ignition devices according to Figures 6A and 6B or according to the F i g. 7A, 7B and 7C pumpable oil quantities should be set so that a certain The degree of purity of the oil in the lubrication system is maintained

In the case of the so far based on FIG. 4 to 7C Oil in small quantities is continuously added to the fuel tank 14 during operation of the device Machine powered, and the oil level in the oil pan 24 is kept at an appropriate level by means of the float valve 62, which the from the Oil tank 32 regulates the amount of fresh oil fed into the oil pan 24. The cross section of the oil feed line 34 should preferably in a range between 1 mm and 2 mm in diameter to avoid excessive to avoid oil feed when the oil level in the oil pan 24 changes rapidly at the moment.

In Fig. 8 shows an electrical circuit.

which completely empties the oil pan through the lubrication system without replacing the old oil with fresh oil prevented. If it z. B. becomes impossible to supply oil to the lubrication system due to a shortage of oil in the oil tank 32

promote, it becomes necessary to stop the drainage of oil from the lubrication system. To do this the float valve 62 is equipped with a limit switch 72 (see also FIG. 5A) to enable a detect excessive drop in the oil level in the oil pan 24. The limit switch 72 is via a manual switch 98, which is normally closed, connected to a battery 96. With the Limit switches 72 are a timer 100, an alarm buzzer 102 and a valve 78 interconnected so that the timer when the limit switch remains closed for a predetermined period of time (e.g. 10 seconds), is triggered to send an output signal to the Alarmsi'mmer 102 and deliver to valve 78. The alarm buzzer 102 generates a buzzer on receipt of the Output ;; igna! It from the timer 100. There? Valve 78 is caused to shut off the oil line 76 (FIG. 4) in order to prevent oil from being drained from the lubrication system to stop. The generation of the output signal by means of the timer 100 is closed compared to the point in time which the limit switch is closed is delayed. This delay is provided to reduce the Actuation of the alarm buzzer 102 and the valve 78 for temporary fluctuations in the oil level in the oil pan 24 to prevent.

When the alarm buzzer 102 begins to generate a buzzer and the driver has recognized that his attention is required, he can the manually operated switch 98 from a position in which is an electrical connection between the battery 96 and the limit switch, into a Bring position in which an electrical connection between the battery 96 and a warning lamp 104 consists. Thus, the annoying buzzing sound is replaced by the lighting of the warning lamp 104 to inform the driver

constantly remind you that the oil level in the oil pan is low.

With the aid of the FIG. 4 to 8 - • «written Device can have a certain degree of purity of the oil in the lubrication system in a permissible range cheaply of a very simple construction and with high reliability.

A third will now be based on FIGS Execution are described. This embodiment is essentially similar to the first embodiment according to the F i g. 1 to 3B, but has modified oil production means.

According to FIGS. 10, II and 12, the oil delivery means in this embodiment comprise an oil line 106, which leads from a main line of a lubrication system to a fuel injection pump 12 As on can best be seen in Fig. 12, the injection pump 12 comprises a housing 108 in which several High pressure fuel channels 22 a are formed, which tubes 22 communicate with high pressure fuel {see also F i g. 10 and 11), which in turn with Fuel injectors 20 communicate. The housing 108 is also provided with a plurality of connection channels 110 provided, each of which has one of the high-pressure fuel channels 22a with a common channel 112 connects which communicates with the oil line 106 In each connecting channel 110 there is a check valve 114 arranged the one-way flow towards the corresponding high pressure fuel passage

22d leaves. V »- as can best be seen from Fig. 13, each check valve 114 includes a spring 116 which has a valve member 118 against one on a valve body 120 trained valve seat presses. The valve body 120 is in the position shown by means of a plug 122 set. Between the valve body 120 of the check valve 114 and the valve body 108 of the A seal 124 is arranged in the fuel injection pump 12. Between the valve body 120 and the Stopper 122, a packing 126 is provided.

As can be seen from Fig. 13, each high-pressure fuel passage 22 a via a discharge valve 134 with a Pump chamber 132 connected. The pump chamber 132 is comprised of a plunger housing 128, one therein movable plunger 130 and a valve body 136 of the Abgabeevoiitils 134 limited. The reference number 138 denotes a spring which presses the dispensing valve 134 into the closed position shown. The high pressure fuel passage 22a extends from the dispensing valve 134 to a corresponding high pressure fuel tube 22.

The sof ^; The conveying means described with reference to FIGS. 10 to 13 operate as follows: The plunger 130 is movable to and fro and sucks fuel into the pump chamber during the suction or downward stroke of the plunger 130. During the upward stroke, the plunger 130 displaces fuel into the pump chamber 132 , pushing the dispensing valve 134 upward against the force of the spring 138 to open the fuel passage therethrough to the high pressure fuel passage 22a. The fuel flows from the high pressure fuel channel 22a to a corresponding fuel injection nozzle 20 (see FIG. 10) via a corresponding high pressure fuel tube 22.

When the plunger 130 begins its downward stroke, the dispensing valve 134 closes under the action of Spring 138. During the stroke of the plunger 130, the dispensing valve 134 settles under the action of the Valve spring 138 on its seat. The dispensing valve 134 is provided with a piston 134a according to FIG. 13 equipped, the makes a suction movement when the dispensing valve is closed. This suction movement leads to a rapid drop in the fuel pressure in the high pressure fuel passage 22a and the fuel injection tube 22. As a result, the fuel Injection aborted sharply, and a lick> on Fuel from fuel injector 20 (Fig. 10) is prevented. This drop in fuel pressure in fuel passage 22a ends up being very sharp the fuel injection according to Figure 9; As a result, fuel pulsation takes place after the fuel injection has been completed.

According to FIGS. 12 and 13, thin oil becomes the common channel 112 from the main line of the

ίο The lubrication system is conveyed via the oil line 106. Of the Pressure is in common channel 112; lower than the remaining pressure in the high pressure fuel passage 22a so that the check valve 114 is normal can close.

The check valve 114, which normally is closed, it is opened whenever a pressure wave occurs, in order to lower the pressure in the high-pressure fuel passage 22a to an instantaneous drop the pressure in common channel 112 increases

Check valve 114 conveys oil through the valve into the High pressure fuel passage 22a.

In this way, a certain amount of oil is transferred from the lubrication system to the fuel system every time

Fuel injection cycle fed. The oil comes with that Mixed fuel and burned together with the fuel in the combustion chambers of the internal combustion engine. If the oil level in the lubrication system is due to the oil discharge drops, the oil feed 34, 36 and 50

(see F i g. 10) switched to the operating position in order to supply oil to the Feed lubrication system.

14 shows a modified valve member 118 ', which the valve member 118 of the check valve 114 can replace. This valve member 118 'is with a Piston surface 140 provided, which when closing the Valve generates a suction movement. Due to the suction movement of the piston surface, a sharp Closing the valve achieved, thereby reducing the time required to close the valve and therefore also the amount of oil fed through each valve opening is reduced. So if it is desired that from the To reduce the amount of oil to be discharged from the lubrication system, the check valve should be equipped with a valve element 118 ' according to FIG. 14 can be used.

In addition 7 sheets of drawings

Claims (15)

Patent claims: 1. Device for automatic oil change in an internal combustion engine with internal combustion with a lubrication system with oil pan (24) and oil tank (32) for fresh oil and euiem fuel system with fuel tank (14), with oil delivery means (28,30; 76,78; 106,12 ) are provided for automatically removing part of the used lubricating oil and oil feed means (34, 36; 62, 64) for automatically supplying fresh oil from the oil tank to the lubrication system, characterized in that the oil delivery means (28, 30; 76, 78; 106, 12) communicate with the fuel tank (14) so that the consumed oil fraction _{) 5} mixes with the fuel in the fuel tank (14) 2. Device according to claim 1, characterized in that the oil conveying an oil line (28), which include one end connected to the lubricating system and their _Μ other end to the fuel tank communicates (14) and a controllable valve (30) in the oil line. 3. Apparatus according to claim 2, characterized in that the oil conveying means comprise an odometer _Μ switch (40), a timer (38), a safety switch (42), an ignition switch (44) and a battery (46), the timer (38) is always switched on for a predetermined period of time when the odometer switch (40) is closed, and wherein the valve is an electromagnetic valve (30) which is electrically connected to the timer (38), the safety switch (42), the ignition switch (44) and the battery (46) is coupled to be supplied with power. 4. Device according to a l.t claims 1 to 3, characterized in that the oil feed means an oil feed line (34), one end of which with the oil tank (32) and the other end of which communicates with the oil pan (24), and one into the Include oil feed line switched on valve (36). 5. Apparatus according to claim 4, characterized in that the oil feed means an ignition switch (44), an oil level switch (50), an oil pressure switch (52), a battery (46) and a timer (48) which during a certain period of time in which both the oil level switch and the oil pressure switch is closed, the device is switched on and the solenoid valve an electromagnetic valve (36) which is electrically so with the timer (48), the ignition switch (44) and the battery (46) is coupled to be supplied with power. 6. Device according to one of claims 1 to 5, characterized in that a switch (40) is assigned to the vehicle distance counter, which turns on the device when the vehicle has traveled a predetermined distance 7. Device according to one of claims 1 to 6, characterized in that means (50) for Measure the oil level in the oil pan (24) and for Switching on the device depending on the measured oil level are provided. 8. Device according to one of claims 1 to 7, characterized in that the oil delivery means a Metering device (80-88; 94) for mechanical metering of a certain amount of machine oil comprise, which enters the oil conveying means from the lubrication system, and that the oil feed means apart from an oil feed line (34), one end of which is connected to the oil tank (32) Float valve (62, 62 '), which is constructed and arranged so that there is a certain Amount of fresh oil can enter the oil pan from the oil feed line, so that the oil level in the Oil pan is maintained at a predetermined level. 9. Apparatus according to claim 8, characterized in that the metering device has a shaft (80) with a central oil channel (84) and with a radial channel (86) extending therefrom, and that a bearing (82) for rotatably supporting the shaft (80) is provided with a channel (88) whose Orifice communicates with the radial channel (86) 10. The device according to claims, characterized in that the metering device has a shaft (80) with a central oil channel (84) and a circumferential groove (92) that includes a channel (86) of the central oil channel to the circumferential groove that a bearing (82) which rotates the shaft (80) supported with a feed line (90) is provided which leads to a feed opening that is always open to the circumferential groove and that a discharge line (88) from a Discharge opening leads to the oil feed line (90), wherein the discharge opening is arranged in a region offset with respect to the circumferential groove, and wherein the shaft is provided with a cutout (94) which opens into the circumferential groove and with the on Can align bearing arranged discharge opening. 11. Device according to one of claims 8 to 10, characterized in that the float valve (62,62 ') has a float (70) with a valve member (66) and a housing surrounding the float, the housing (74) having openings { 74b) for establishing a flow connection between the oil pan located outside the housing and the interior of the housing 12. The device according to claim 1, characterized in that the oil feed means comprise an oil feed line (106), one end of which communicates with the lubrication system, that a fuel injection pump (12) has a plurality of delivery valves (114) and thus communicating high-pressure fuel channels (22a) , wherein a or several connecting channels (110, 112) connect at least one of the high-pressure fuel channels to the oil feed line, and that a check valve (114) is arranged in the connecting channel or channels 13. Apparatus according to claim 12, characterized characterized in that the connecting channels (110, 112) with each of the high pressure fuel channels (22äjcommunicate. 14. A method for changing oil in an internal combustion engine with an internal combustion engine Lubrication system with an oil pan and a fuel system with a fuel tank, with automatic used oil discharged and Krischol in the Tub is refilled, characterized in that the used oil in a metered amount for Fuel tank is promoted and mixed in this with the fuel. 15. The method according to claim 14, characterized in that used oil after returning a predetermined route to the fuel system is promoted and that fresh oil is topped up in the oil pan depending on the oil level will. The invention relates to a device for automatic oil changes in an internal combustion engine internal combustion with a lubrication system with oil pan and oil tank for fresh oil as well as one Fuel system with fuel tank, with oil delivery means for automatically discharging part of the Used lubricating oil and oil feed for the automatic supply of fresh oil from the oil tank are provided for the lubrication system, as well as a procedure for changing the oil. Machine oils that are used as lubricants become inferior after prolonged use and no longer remain in effect. It is therefore necessary to close the öi at regular intervals switch. However, oil changes require Zeitatiwand and costly work Sometimes the oil change is forgotten and, as a result, it is not done on time it is also necessary to check the oil level regularly and, if necessary, to top up oil, oil tests are necessary laborious and are therefore reluctantly carried out. Used oil has to be recycled, what in turn, a costly method requires in a known device of the initially described type (US-PS 34 47 636) is used oil at the instigation of the driver in the upper part a "reserve cartridge" is pumped, whereby fresh oil from this reserve cartridge into an intermediate container is displaced and fed to the engine. The reserve cartridge must then be replaced. Furthermore, an oil filter and mixing device for supplying a fuel-oil mixture for combustion either in diesel engines or two-stroke engines is known, which require an oil component for piston lubrication (DE-OS 27 36 153). Here is Used oil is first cleaned in a filter, then mixed with fuel and then fed into the combustion chamber oil sump is consumed, an oil change must be made in a known manner. The invention is based on the object of a device and a method for automatic To train oil changes of the type described in US-PS 34 47 636 that a removal consumed Lubricating oils practically unnecessary To solve this problem is in a device of the type mentioned according to the invention that the oil delivery means with the fuel tank communicate so that the oil used is mixed with the fuel in the fuel tank A method according to the invention is characterized according to the invention in that the used oil is conveyed in a metered amount to the fuel tank and mixed in this with the fuel. According to the invention, the used oil is thus fed to the combustion process. The invention is accordingly used with advantage in diesel engines and two-stroke Otto Majchinen. Advantageous further developments of the invention are provided in the subclaims and protection. The invention is illustrated below with the aid of schematic drawings of exemplary embodiments explained in more detail with further details It shows 1 shows a schematic overview of a preferred embodiment of a device for automatic oil change and removal of used oil according to the invention; F i g. FIG. 2 shows a block diagram of a control circuit which is used in the device according to FIG. 1 is applied; 3A and 3B are views of an odometer switch which is used in the circuit according to FIG. 2 is used, wherein Fig.3A the number wheels of the displacement meter provided with a switching contact and Fi g. 3B a Number wheel with the switching contact and with a stationary switching element that interacts with it represent; FIG. 4 is a view similar to FIG. 1 of a second Execution of a device according to the invention; 5A shows a sectional view of a float valve, that in the device according to FIG. 4 is used; Fig.5ß a section through c ^J ne modified embodiment of the float valve according to F ig, 5A; FIG. 5C shows a horizontal section through the float valve according to FIG. 5B; 6A shows a section along the line VLA-VlA in 6B, which shows a bearing in which a camshaft is rotatably supported, with a portion machine oil can enter an oil line leading to a fuel system; FIG. 6B shows a longitudinal section through the bearing according to FIG. 6A; F i g. 7A shows a cross section along the line VIIS-VIIA in Figure 7B, wherein a bearing similar to that of Figure 6A is shown in a modified form, the one Allows portion of machine oil to enter an oil line leading to the fuel system; F i g. 7B shows a section through the bearing according to FIG. 7A; F i g. 7C is a perspective view of the FIG. 7A depicted bearing; F i g. 8 shows a block diagram of a fail-safe and alarm circuit for shutting down the device according to FIG F15.4, which part of the machine oil from the Promotes lubrication system to fuel system; 9 shows a diagram for the fuel injection pressure over time; Fig. 10 is a view similar to Fig.l a third Execution of a device for automatic oil change and removal of used oil according to the invention; F i g. 11 is an enlarged detail from FIG. 10; 12 shows a section along the line XH-XH in G; 13 shows a partial section along the line XIH-XIH in Fig. 12 and F i g. 14 is a perspective view of a valve member of a check valve used in the embodiment according to FIG. 12 and 13 is used Fig. 1 shows an internal combustion engine 10 with internal Combustion with a fuel system that has a Fuel injection pump 12, a fuel tank 14, a fuel feed line 16, a fuel filter 18, Fuel injectors 20 and high pressure fuel passages 22 include. The fuel supply line 16 leads from fuel tank 14 to injection pump 12 to Fönjtrn fuel from fuel tank 14 to injection pump Yi. The fuel is "filtered" when it passes through the filter 18. The injection pump 12 delivers fuel to the injection nozzles 20 via the